First Report of Cercospora Leaf Spot Caused by Cercospora cf. flagellaris on Lonicera japonica Thunb. in Henan, China.

Honeysuckle flower (Lonicera japonica Thunb.) is a traditional Chinese medicinal plant. It is perennial and widely cultivated in China, Japan and Korea. From late August to October in 2021 and 2022, leaf spots symptoms were observed on L. japonica in different planting fields in Yuzhou, Yuanyang and Fenqiu districts, Henan province, China. The disease incidence was above 85% which reduce photosynthesis. Early disease symptoms appeared as small, circular to elliptical, brown spots on the leaves and later the lesions (1 to 5 mm × 1 to 4 mm) slowly developed yellow haloes. The different brown lesions seldom merge and form larger irregular lesions. Small fragments (3 to 5 mm) of leave tissue were excised from the lesion margins and surface-sterilized in 3% NaClO for 3 min, followed by three washes with sterile distilled water, and then placed on potato dextrose agar (PDA) and incubated at 25°C in the dark for 5 days. A total number of 8 cultures were obtained and purified by single-spore subcultures on PDA for morphological identification. The colonies on PDA were whitish to gray, with cottony aerial mycelium. Conidiophores were fasciculate, olivaceous brown, straight or geniculate, uniform in width, multiseptate, and ranged from 290 to 700 µm (560 µm on average, n = 20). Conidia were hyaline, slightly curved or straight, needle shaped, truncate at the base, and terminal at the tip, 3 to 17-septate, and measuring 150 to 240 µm (180 µm on average, n = 20). The morphological features were consistent with Cercospora cf. flagellaris Ellis & G. Martin (Groenewald et al. 2013). The genomic DNA was extracted using CTAB method. The nuclear ribosomal internal transcribed spacer region (ITS), portions of the actin (ACT), histone H3 (HIS3), and translation elongation factor 1-α (TEF1) genes were amplified using primers ITS1/ITS4 (Groenewald et al. 2013), ACT-512F/ACT-783R (Carbone and Kohn 1999), CYLH3F/CYLH3R (Crous et al. 2006), and EF1-728F/EF1-986R (Carbone and Kohn 1999). The resulting 537-bp ITS, 226-bp ACT, 410-bp HIS3, and 306-bp TEF1 sequences of isolate JDJ002 were deposited in GenBank (accession nos. OR492367, OR548247, OR548248 and OR548248, respectively). Sequence analysis revealed that ITS, ACT, HIS3 and TEF1α sequences exhibited ≥99% of identity with the ITS (KP896013), ACT(KP895965), HIS3(MK991295) and TEF1 (MN180408) sequences of C. cf. flagellaris, respectively. A pathogenicity test was conducted on healthy of L. japonica leaves. The healthy leaves pricked from L. japonica plants, rinsed in autoclaved distilled water three times and dried with distilled filter paper. Then twelve healthy leave were inoculated with a mycelial plug (0.4 cm diameter) harvested from the periphery of two week-old colony. As negative control, leaves inoculated with PDA medium plugs. Inoculated leaves were covered with plastic bags to maintain high relative humidity and incubated at 25°C in growth chamber. After 7 days, the inoculated leaves showed symptoms identical to those observed in the field under natural conditions, whereas negative control remained symptom-free. Re-isolation of the fungus from lesions on inoculated leaves confirmed that the causal agent was C. cf. flagellaris. Pathogenicity tests were repeated three times by the same methods with the same results. To our knowledge, this is the first report of C. cf. flagellaris except Cercospora rhamni Fack., Alternaria alternata, Corynespora cassiicola or Phomopsis sp. causing leave spots on L. japonica in China.

Examining Poverty Reduction of Poverty-Stricken Farmer Households under Different Development Goals: A Multiobjective Spatio-Temporal Evolution Analysis Method.

Accurately identifying the degree of poverty and poverty-causing factors of poverty-stricken farmer households is the first key step to alleviating absolute and relative poverty. This paper introduces a multiobjective spatio-temporal evolution analysis method to examine poverty reduction of poverty-stricken farmer households under different development goals. A G-TOPSIS model was constructed to evaluate poverty-stricken households under short-, medium-, and long-term development goals. Then, GIS analysis methods were employed to reveal the spatio-temporal distribution of poverty-stricken households, and poverty causing factors were detected using the obstacle degree model. Taking Fugong County in Yunnan Province, China, as an example, the empirical results show that: (1) Great progress has been made in poverty reduction during the study period; however, some farmer households which have escaped absolute poverty are still in relative poverty and are still highly vulnerable. (2) Farmers with higher achievement rates under three different development goals are mainly distributed in the central and northern regions of study area, with a pattern of high-high agglomeration under the medium and low development goals, while low-low agglomeration mostly appears in central-southern regions. (3) Under the short-term development goals, the main poverty-causing factors are per capita net income, safe housing, sanitary toilets, years of education of labor force and family health. Under the medium- and long-term goals, per capita net income, labor force education and safe housing are the development limitations. (4) Infrastructure and public service are crucial to ending absolute poverty, and the endogenous force of regional development should be applied to alleviate the relative poverty through sustainable development industries and high-quality national education.

First Report of Youcai Mosaic Virus Infecting Yam in China.

Yam (Dioscorea opposita Thunb.) is cultivated mainly as a functional food and for nutritional and medicinal purposes in China (1). It is propagated through tubers and this facilitates the spread and accumulation of viruses in the crop, eventually leading to yield losses (2). At present, different virus species belonging to the genera Aureusvirus, Badnavirus, Carlavirus, Comovirus, Cucumovirus, Fabavirus, Macluravirus, Potexvirus and Potyvirus have been reported in yams (3) and fifteen viruses in these genera have been detected in China. In July 2020, a survey of viral diseases on yam was conducted in plantations of Wenxian and Mengzhou counties in Henan Province, China. Fifty-four leaf samples of Dioscorea opposite showing mosaic and leaf discoloration (Supplementary Fig1) were collected from eight fields (five to ten plants per field). These leaf samples were ground in liquid nitrogen and total RNA was extracted from a portion of the mixed powder using RNAprep Pure Plant Plus Kit (TIANGEN Biotech, Beijing, China). A cDNA library was constructed using NEBNext Ultra RNA Library Prep Kit for Illumina (NEB, USA) after ribosomal RNA depletion using Ribo-off rRNA Depletion Kit (Vazyme Biotech, Nanjing, China), and sequenced on the Illumina NovaSeq 6000 system at the Berry Genomics Corporation (Beijing, China). A total of 87,075 contigs (>200 bp) were generated from de novo assembly (CLC Genomic Workbench 10.0) from a total of 34,656,172 paired-end reads. After BLASTn analysis, three contigs with the length of 1009, 1340 and 1859 nucleotides shared 96.33%, 96.72% and 96.29% nt identity respectively with youcai mosaic virus SX isolate, a tobamovirus (YoMV GenBank accession no. JX422022). In addition to YoMV, broad bean wild virus 2 and yam latent virus were also identified, which had previously been reported in yams in China. To confirm the NGS result, total RNAs were extracted from fifty-four above-mentioned samples and RT-PCR was carried out to amplify a 528 bp fragment of the coat protein (CP) of YoMV by using a pair of specific primers CP gene. PCR products with expected size were obtained from 26 out of 54 samples, and seventeen amplicons of YoMV-CP were sequenced (accession nos. ON052726 to ON052742). The nt sequence identities of CP gene among these seventeen isolates were 99.6%-100%. Furthermore, the near-full-length genomic sequence of YoMV-Do41 isolate was obtained from sample 41 by RT-PCR amplification of four overlapping fragments using the following primer pairs: YoMV-15F/YoMV-1910R, YoMV-1770F/YoMV-3750R, YoMV-3645F/YoMV-5404R and YoMV-4921F/YoMV-6280R (Supplementary Table1). The YoMV-Do41 isolate was 6, 274 nt in length (accession no. ON149803) and shared 89.65% and 97.31% nt identities to As1-2 isolate (GenBank accession no. MW307290) and to SX isolate (accession no. JX422022), respectively.To the best of our knowledge, this is the first report of YoMV infecting yam in China. YoMV has a wide host range including genera Impatiens, Rehmannia, Brassica, Chelidonium, Trifolium, Crossandro, Alstroemeria, Stellaria. This study will serve as an important reference for the host range of YoMV. According to the detection rate infections with YoMV in yam are common in these producing regions. Further studies will be required to determine the infection rate in other producing regions and the potential threat posed by YoMV on yam production should be considered.

First Report of Tobacco Mild Green Mosaic Virus Infecting Rehmannia glutinosa in China.

Rehmannia glutinosa (family Scrophulariaceae) is an important traditional medicinal plant, whose root is used to treat anemia, hemoptysis, and gynecological diseases in China (Matsumoto et al. 1989). This plant is native to China and cultivated in China, Korea, Japan, and northern Vietnam (Kwak et al. 2020). Viral diseases caused remarkable loss in the yield and quality of R. glutinosa (Ling et al. 2009). To date, ten viruses have been identified globally to infect R. glutinosa and seven of these viruses reported in China (Liu et al. 2018; Zhang et al. 2021). Most plants of R. glutinosa are infected with one or more of these viruses (Kwak et al. 2018; Zhang et al. 2004). In July 2020, a survey of the viral disease infecting R. glutinosa was conducted in commercial plantations of Wenxian, Wuzhi, Mengzhou, and Yuzhou counties in Henan Province, China. The disease symptoms included mosaic, chlorosis, leaf distortion, and the percentage of symptomatic plants was over 70% in the surveyed fields (n=9). Sixty leaf samples of symptomatic R. glutinosa plants were collected from nine cultivation fields in Wenxian, Wuzhi, Mengzhou, and Yuzhou counties (five to seven plants for each field). Total RNA was extracted from one pooled sample containing a portion of all above-mentioned leaf samples using RNAprep Pure Plant Plus Kit (TIANGEN Biotech, Beijing, China) and analyzed by high-throughput sequencing (HTS) to identify viral pathogens. A transcriptome library was generated using NEBNext Ultra RNA Library Prep Kit for Illumina (NEB, USA), and sequenced on an Illumina NovaSeq6000 sequencing system at Berry Genomics Corporation (Beijing, China). A total of 27,664,949 high-quality clean reads were obtained after trimming and used for contig assembly. The assembled contigs (n=109,180) were searched using Basic Local Alignment Search Tool (BLAST) at GenBank. BLASTn analysis showed that the R. glutinosa plants were infected with known viruses, including broad bean wilt virus, rehmannia mosaic virus, youcai mosaic virus, and cucurbit chlorotic yellows virus. In addition, one contig (6,418 nt in length) had a nucleotide sequence identity of 99.64% with the TN29 isolate of tobacco mild green mosaic virus (TMGMV, GenBank accession no. MF139550). To confirm the presence of this virus, sixty above-mentioned samples were screened by reverse transcription-polymerase chain reaction (RT-PCR) using the specific primer pairs (Supplementary Table1) TMGMG-CPF/TMGMG-CPR targeting a 545-nt fragment within the CP gene. Amplicons with expected sizes were detected from 47 of 60 samples but not from the negative control (virus-free healthy plant through the tip meristem culture). Seventeen amplicons (11#, 13#, 14#, 21#, 22#, 23#, 25#, 26#, 27#, 31#, 32#, 33#, 37#, 52#, 57#, 59#, and 60#) of TMGMV-CP were selected, and purified. The PCR products were cloned into the pMD19-T vector (TAKARA Biotech, Dalian, China) and sequenced. The sequences were deposited into the GenBank (accession nos. MZ395944 to MZ395960). The near-full-length genomic sequence of TMGMV-Rg14 isolate was obtained from one positive sample (sample no. 14) by RT-PCR amplification of two overlapping fragments using the following primer pairs: TMGMV-40F/TMGMV-3570R and TMGMV-3220F/TMGMV-6400R. The near-full-length genomic sequence of the TMGMV-Rg14 isolate was 6 304 nucleotides (nt) in length and deposited into GenBank (accession no. MZ395975). BLASTn analysis demonstrated that the TMGMV-Rg14 isolate shared a sequence identity ranging from 96.89% (AB078435) to 99.60% (MF139550) with the other TMGMV isolates. Furthermore, the virus-free healthy R. glutinosa plants were inoculated with sap from the positive sample (14#) to confirm the infection of TMGMV. Mosaic symptoms were induced on the systemically infected leaves of the inoculated plants 14 days post inoculation. The systemically infected leaves of inoculated plants were assayed by RT-PCR using the primer pairs TMGMV-CPF/CPR. Amplicons of expected size were detected from the inoculated plants but not from non-inoculated plants. To our knowledge, this is the first report of TMGMV infection on R. glutinosa. Further studies are necessary to select a suitable indicator plant for this TMGMV, its host range, and the symptoms it induces in single infection. Since R. glutinosa is cultivated by vegetative propagation, production of virus-free healthy plants is necessary. This study will help to generate virus-free healthy plants and prevent viral disease on R. glutinosa. Further study is needed to determine its pathological implications and economic impact on R. glutinosa in China.

Effect of 0.01% Atropine on Accommodation in Myopic Teenagers.

Purpose: The purpose of the study is to evaluate the effects of 0.01% atropine eye drops on accommodative system parameters among teenagers with low myopia. Methods: Ninety-five myopic teenagers [39 boys (8.69 ± 2.473) and 56 girls (8.54 ± 2.054) aged 5-17 years] with no history of eye disease were enrolled. Biometric and accommodative system parameters were evaluated before and at 1 week, 1 month, 3 months, and 6 months of 0.01% atropine eye drop instillation. Results: Participants without accommodative demand at 6 months demonstrated insignificant changes after the atropine instillation (all p > 0.05). Nevertheless, there were significant differences in accommodative sensitivity, accommodative amplitude, accommodative responsiveness, and negative relative accommodation (NRA) at 3 months compared with baseline after atropine instillation (all p < 0.05). Except spherical equivalent refraction, cornea thickness, intraocular pressure, and axial length were stable after the 0.01% atropine instillation (all p > 0.05). Conclusion: Morphologically, current measurements suggested that 0.01% atropine had favorable reduction of accommodation for childhood low myopia over a half-year period.

First Report of Dasheen Mosaic Virus Infecting Typhonium giganteum Engl. (Baifuzi) in Henan Province of China.

Typhonium giganteum Engl. (Baifuzi ) is a perennial plant of the family Araceae. In China, its root is commonly used as an antispasmodic for stroke and cancer treatment (Chi et al. 2010; Gao et al. 2014; Khalivulla et al. 2019). Yuzhou city in Henan Province is the main producing area of T. giganteum Engl., and in July 2020, a survey of viral disease infecting T. giganteum Engl. was conducted in the city. In the surveyed fields (n =5), over 60% of plants displayed varying levels of virus-like symptoms, including mosaic, chlorotic and leaf distortion (Supplementary Figure S1) . To identify possible viral pathogens associated with the disease symptoms afflicting T. giganteum Engl., one leaf each from 25 symptomatic plants was collected and analyzed by high-throughput sequencing (HTS) as well as PCR. For HTS analysis, total RNA was extracted from one pooled sample containing a portion of all abovementioned leaves using RNAprep Pure Plant Plus Kit (TIANGEN Biotech, Beijing, China). After removing ribosomal RNA with Ribo-off rRNA depletion kit (Vazyme Biotech, Nanjing, China), a sequencing library was generated using NEBNext Ultra RNA Library Prep Kit for Illumina (NEB, USA) and sequenced on an Illumina Novaseq6000 sequencing system at Berry Genomics Corporation (Beijing, China). A total of 6,899,143 high-quality clean reads were obtained after trimming and used for contig assembly. BLASTn and BLASTx analyses on the contigs (n = 128,400) showed that one contig (9,245 bp in length) exhibited a sequence identity of 84.0% with the reference sequence of dasheen mosaic virus (DsMV, NCBI reference seq. NC_003537, genus Potyvirus, family Potyviridae) , suggesting infection of the plants by DsMV. No other viral sequences were detected in the sample. To confirm these results, a near full-length genomic sequence of DsMV was obtained from one sample (sample no. 39) by reverse transcription polymerase chain reaction (RT-PCR) of three overlapping fragments with the following primer pairs: DsMV-1F (5'-AAATTAAAACATCTCAACAAAACCTACA-3') /DsMV-4130R (5'-TTCATGGTCCTCGTGGAGTATA-3'), DsMV-3870F (5'-GAGGACGTGAGAATTCAAAGTCT-3')/DsMV-8250R (5'-GTCCAACCTTGCTTGATGCATGC-3'), DsMV-7690F (5'-GGAGCGACTCCTCTTCCAAAGTTGTG-3')/DsMV-10100R (5'-TGAACACCGTGCACGAAGCATCTC-3'). The PCR products were cloned into pMD19-T vector (TAKARA Biotech, Dalian, China) and sequenced. The near full-length genomic sequence of the isolate (DsMV-BF39) was 9,737 nt in length and deposited into GenBank under the accession no. MZ043618. BLASTn analysis of this sequence demonstrated that it shared an identity ranging from 78.6% (MG602234) to 85.6% (MG602227) with various DsMV isolates. To determine whether DsMV was closely associated with the symptoms observed in T. giganteum Engl., leaf tissues from 30 symptomatic plants and 22 asymptomatic plants were analyzed by RT-PCR using primer pairs DsMV-CPF (5'-TGTTCTGTGAACATGATGAAGTTG-3', sense) and DsMV-CPR (5'-GTAACTGTGGCCTGTTTACCAG-3', antisense) targeting a 916 bp fragment of the CP gene of DsMV. Amplicons with the expected size were detected from the 30 symptomatic plants but not from the 22 asymptomatic plants, suggesting a close association between DsMV infection and the observed symptoms. To our knowledge, this is the first report of DsMV infecting T. giganteum Engl.. Further study is needed to identify the specific symptoms induced by this virus in T. giganteum Engl. and to understand the biological characteristics, epidemiology, prevalence of this virus in China.

[Coupling between ecological environment vulnerability and multidimensional poverty: An empirical analysis from 1586 poverty-stricken villages in Hechi City, Guangxi, Southwest China]. / ç”Ÿæ€çŽ¯å¢ƒè„†å¼±æ€§ä¸Žå¤šç»´è´«å›°çš„è€¦åˆå ³ç³»­­åŸºäºŽå¹¿è¥¿æ²³æ± 市1586个贫困村的实证分析.

Examining the interaction mechanism between ecological environment and regional poverty at fine scale is an important prerequisite and guarantee for sustainable development of resources, environment and social economy from the combined perspectives of precise poverty alleviation and rural revitalization. We established the evaluation models of ecological vulnerability, multidimensional poverty, and the coupling coordination degree model, beased on which we systematically and comprehensively revealed the interaction between ecological environment and multidimensional poverty. The test results from 1586 administrative villages showed that the higher-vulnerability area of ecological environment was mainly distributed in the southeast region. Multidimensional poverty was increasing from northwest to southeast, with a spatial distribution pattern of "overall dispersion, local aggregation". In the coordinated development zone, ecological environment vulnerability and multidimensional poverty was positively correlated. In the disordered declining zone, the degree of coupling between ecological environment vulnerability and multidimensional poverty was lower, wth significantly negative correlation, indicating that the improvement of ecological environment quality and the development of multidimensional poverty reduction were asynchronous. There was a close and complex relationship between eco-environmental vulnerability and multidimensional poverty. Therefore, during poverty alleviation and development, we should pay more attention to environmental protection to prevent the poverty-stricken areas falling into the trap of ecological poverty.